Induction of Interleukin-1 Associated with Compensatory Dopaminergic Sprouting in the Denervated Striatum of Young Mice: Model of Aging and Neurodegenerative Disease

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The Journal of Neuroscience, August 1, 1998, 18(15):5614-5629

Induction of Interleukin-1 Associated with Compensatory Dopaminergic Sprouting in the Denervated Striatum of Young Mice: Model of Aging and Neurodegenerative Disease
Angela Ho and Mariann Blum
Fishberg Research Center for Neurobiology, Mount Sinai School of Medicine, New York, New York 10029

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Young mice challenged with the neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), which selectively destroysthe substantia nigra dopaminergic neurons in the midbrain, exhibitspontaneous recovery of dopaminergic nerve terminals. However,such recovery becomes attenuated with age. Here we report thatnewly sprouted fibers originate from spared dopaminergic neuronsin the ventral tegmental area. We found that interleukin-1 (IL-1),an immune response-generated cytokine that can enhance dopaminergicsprouting when exogenously applied, increased dramatically inthe denervated striatum of young mice (2 months) compared withmiddle-aged mice (8 months) after MPTP treatment. Young mice displayeda maximal 500% induction of IL-1 $alpha$ synthesis that remained elevatedfor several weeks in the dorsal and ventral striatum, whereasmiddle-aged mice exhibited a modest 135% induction exclusivelyin the dorsal striatum for a week. IL-1 $alpha$ immunoreactivity waslocalized in GFAP-immunoreactive hypertrophied astrocytes andneurons within the denervated striatum of young mice. However,no induction of IL-1 $alpha$ mRNA was seen in the midbrain in eitherage group despite glial activation. Because we have reported thatIL-1 can regulate astroglia-derived dopaminergic neurotrophicfactors, it was surprising that no changes were observed in acidicand basic fibroblast growth factor or glial cell line-derivedneurotrophic factor mRNA levels associated with MPTP-induced plasticityof dopaminergic neurons in the striatum of young mice. Interestingly,we found that dopaminergic neurons express IL-1 receptors, thussuggesting that IL-1 $alpha$ could directly act as a target-derived dopaminergicneurotrophic factor to initiate or enhance the sprouting of dopaminergicaxonal terminals. These findings strongly suggest that IL-1 $alpha$ couldplay an important role in MPTP-induced plasticity of dopaminergicneurons.

Key words: IL-1; compensatory sprouting; dopaminergic neurons; growth factors; MPTP; Parkinson's disease; aging

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The mesostriatal dopaminergic system plays an important role in the control of voluntary movement. This system comprises midbraindopaminergic cell groups and their projections to the entire striatalcomplex that consists of a dorsal and ventral component (Björklundand Lindvall, 1984). In the rodent, the dorsal striatum (caudate-putamen)is innervated mainly by dopaminergic neurons in the substantianigra pars compacta (SN), whereas the ventral striatum (nucleusaccumbens and the olfactory tubercle) receives projections fromcells in the ventral tegmental area (VTA) and the retrorubralarea (Björklund and Lindvall, 1984). Selective degeneration ofthe mesostriatal pathway leads to motor impairments in Parkinson'sdisease (PD), which is characterized by the loss of dopaminergicneurons in the SN that leads to a preferential depletion in dopaminergicinnervation of the dorsal striatum; however, cells in the VTAand the retrorubral area are much less affected (Agid et al.,1987; Hirsch et al., 1988; German et al., 1989; Hornykiewicz,1993).

A neurotoxin, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), that selectively destroys the SN dopaminergic cells hasbeen used to produce an animal model of PD (Langston, 1985; Singerand Ramsay, 1990). In experimental animals, the neurodegenerativeeffects of MPTP are age-dependent; that is, young mice show asubstantial recovery of striatal dopamine, whereas aged mice donot (Ricaurte et al., 1986, 1987a,b; Date et al., 1990a). Thus,the dopaminergic cell system exhibits compensatory mechanismsin response to injury, and the degree of plasticity becomes reducedwith age (Hornykiewicz, 1993). In this report, we sought to determinethe origin of dopaminergic fibers responsible for the spontaneousaxonal regrowth in the denervated striatum of young mice. Moreimportantly, we examined the cellular and molecular events associatedwith the dopaminergic sprouting that occurs selectively in thedenervated striatum of young but not middle-aged mice after MPTPtreatment.

Glial cells play an integral role in the brain response to neuronal injury and plasticity (Eddleston and Mücke, 1993; Mooreand Thanos, 1996). Injury to the brain elicits a sequence of morphologicaland biochemical events mediated by activated microglia that canrelease inflammatory cytokines such as interleukin-1 (IL-1) (Giulianet al., 1986, 1987, 1989, 1990). IL-1, in turn, can stimulatereactive astrocytes and enhance the synthesis of neurotrophicfactors from astrocytes, thereby promoting axonal sprouting (Giulianand Lachman, 1985; Giulian et al., 1988; Spranger et al., 1990;Araujo and Cotman, 1992). It was shown that intrastriatal implantationof IL-1 can enhance compensatory sprouting from residual dopaminergicneurons in the VTA and can induce behavioral improvement in hemiparkinsonianrats (Wang et al., 1994). Recently, we have reported that basicfibroblast growth factor (bFGF) may be the putative dopaminergicneurotrophic factor that mediates IL-1 lesion-induced plasticityof dopaminergic neurons because intraventricular administrationof IL-1 induces bFGF gene expression (Ho and Blum, 1997).

In the present study, we investigated the potential role of IL-1 and trophic factor activities in mediating the spontaneousdopaminergic sprouting in the denervated striatum of young butnot middle-aged mice after MPTP treatment. We hypothesized thatperhaps in the aging brain, the ability to induce growth-promotingmolecules such as IL-1 and the subsequent induction of trophicfactor synthesis declines with age. An understanding of the cascadeof cytokine and trophic factor activities could provide insightsinto basic mechanisms of aging and their relationship to the processof dopaminergic cell death in PD.

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Drug administration. Male C57BL/6 mice (Harlan Sprague Dawley, Indianapolis, IN) of two different age groups were used: 8weeks (young) and 8 months (middle-aged) of age. MPTP hydrochloride(Research Biochemicals, Natick, MA) was administered subcutaneously.Young mice received a single dose of MPTP at 55 mg/kg, and middle-agedmice received a single dose at 40 mg/kg. These doses were selectedbased on titration studies that produced comparable initial depletionsof dopamine uptake in the striatum of young and older mice. Age-matchedcontrols received saline. Animals were killed at 4, 8, 14, 21,and 30 d after the lesion along with their age-matched controls(n = 4-5/group). All animal experiments were conducted accordingto the Guidelines for the Care and Use of Experimental Animals,using protocols approved by the Institutional Animal Care andUse Committee at Mount Sinai School of Medicine (95-300NB).

[³H]Dopamine uptake. Animals were decapitated, and the brains were quickly removed and placed into cold sterile saline. Thedorsal and ventral striatum were dissected, and the anterior commissurewas used as an anatomical landmark to distinguish between thedorsal and ventral striatum. Tissue above the anterior commissurewas removed bilaterally and collected for the dorsal striatum,whereas tissue below the anterior commissure was collected forthe ventral striatum. Tissues were homogenized in 500 µl of ice-coldprelysis buffer (10 mM Tris, pH 7.5, and 0.32 M sucrose) usinga Teflon pestle-glass mortar pair as described by Roffler-Tarlovet al. (1990). Homogenized tissue (100 µl) was removed and centrifugedfor 10 min at 1000 × g at 4°C to remove nuclei. The supernatantcontaining the synaptosomes was collected, and aliquots were removedfor the determination of protein concentration and dopamine uptake(total high-affinity and mazindol noninhibitable). Fifty microlitersof supernatant were diluted in 450 µl of Krebs-Ringer phosphatebuffer (0.1 M) with added EDTA (1.3 mM), glucose (5.6 mM), andascorbic acid (0.2 mg/ml) and incubated at 37°C in the presenceor absence of 10 µM mazindol (Research Biochemicals), a high-affinitydopamine uptake inhibitor. [³H]Dopamine (specific activity, 20-40 Ci/mmol; Amersham, ArlingtonHeights, IL) was added to a final concentration of 0.025 µM, andincubation was at 37°C for 6 min. Synaptosomes were collectedon presoaked nitrocellulose filters by filtration, and nonspecificradioactivity was washed with Krebs-Ringer phosphate buffer followedby filtration. The filters were then transferred into scintillationvials of Hionic-fluor and measured by liquid scintillation spectrometry.Specific high-affinity neuronal dopamine uptake was expressedas femtomoles of dopamine uptake per microgram of protein minusthe femtomoles of mazindol uptake. Values are presented as thechange in dopamine uptake (expressed as percent of control).

Immunocytochemistry. Animals were anesthetized with Rompun xylazine and Ketaset (1:1) and killed by intracardiac perfusionwith 1% paraformaldehyde in 0.15 M phosphate buffer, pH 7.2 (PBS),followed by 4% paraformaldehyde. Brains were post-fixed for 5hr at 4°C and cryoprotected with 30% sucrose. Tissues were frozenwith ornithine carbamyl transferase (Tissue Tek, Torrance, CA)embedding medium immersed in a dry-ice-chilled isopentane bath.Thirty micrometer coronal sections were cut using a cryostat andwere processed for immunocytochemistry. Sections were incubatedin blocking buffer (0.3% Triton X-100 and 3% goat serum in PBS)for 30 min, followed by an overnight incubation with primary antibodiesto tyrosine hydroxylase (rabbit polyclonal anti-TH, 1:500; Pel-FreezeBiologicals, Rogers, AR), glial fibrillary acidic protein (rabbitpolyclonal anti-GFAP, 1:50; Biomeda, Foster City, CA), or microglia(rat monoclonal anti-Mac-1, 1:50; Boehringer Mannheim, Indianapolis,IN) in blocking buffer at 4°C. Sections were then washed threetimes for 10 min each with PBS and incubated in biotinylated anti-rabbitIgG to detect TH and GFAP (1:200; Vector Laboratories, Burlingame,CA) or rat IgG to detect Mac-1 (1:200; Amersham) for 2 hr at roomtemperature. Sections were washed and then incubated in ExtraAvidin(1:200; Sigma, St. Louis, MO) for 1 hr at room temperature. Sectionswere washed and processed with 0.05% 3,3'-diaminobenzidine tetrachloride(Sigma) with 0.003% H₂O₂. After processing, sections were washed,mounted on coated slides, dried, dehydrated through graded alcohols,cleared in xylene, and coverslipped in DPX mountant medium (ElectronMicroscopy Sciences, Fort Washington, PA).

Double immunolabeling. Young mice lesioned with MPTP and killed at 8 d along with saline-matched control were processed forcombined fluorescence immunocytochemistry for IL-1 $alpha$ (rabbit polyclonalanti-mouse IL-1 $alpha$ , 1:400; Genzyme, Cambridge, MA) and GFAP (mousemonoclonal anti-GFAP, 1:50; Boehringer Mannheim), IL-1 $alpha$ and Mac-1,IL-1 $alpha$ and Neu N (mouse monoclonal anti-neuronal nuclei, 1:500;Chemicon International, Temecula, CA), and IL-1 receptor (ratmonoclonal anti-IL-1 receptor, 1:400; Genzyme) and TH. Sectionswere incubated in blocking buffer (0.1% saponin and 3% goat serumin PBS) for 30 min, followed by an overnight incubation of primaryantibody in blocking buffer at 4°C. IL-1 $alpha$ was visualized by incubationwith anti-rabbit IgG directly conjugated to fluorescein (1:200;Vector Laboratories), whereas GFAP, Mac-1, and Neu N immunoreactivitywas reacted to appropriate biotinylated secondary antibodies [anti-mouseIgG to detect GFAP and Neu N (1:200; Vector Laboratories) andanti-rat IgG to detect Mac-1 (1:200; Amersham)] for 2 hr followedby incubation in streptavidin conjugated to rhodamine (1:500;Molecular Probes, Eugene, OR). For IL-1 receptor and TH immunoreactivity,TH was visualized by incubation with anti-rabbit IgG directlyconjugated to fluorescein, whereas IL-1 receptor was reacted tobiotinylated anti-mouse IgG for 2 hr followed by incubation instreptavidin conjugated to rhodamine. After processing, sectionswere mounted on coated slides, dried, and coverslipped in Permafluor(Lipshaw, Pittsburgh, PA) mounting medium.

Retrograde labeling. To detect degeneration of dopaminergic neurons after MPTP lesion and to identify the cellular originof the sprouted fibers in the dorsal striatum, we used young micebefore MPTP lesion or treated after 30 d with saline and MPTP,respectively. Animals were anesthetized with avertin at 287.5mg/kg (stock of 2,2,2-tribromoethanol at 12.5 mg/ml; Aldrich,Milwaukee, WI), injected intraperitoneally. The mice were placedon a stereotaxic device (David Kopf Instruments, Tunjunga, CA).A burr hole was drilled on the right side of the skull to accommodateinjection. Stereotaxic injections of 0.35 µl of fluorescent latexmicrosphere "beads," a retrograde neuronal tracer (Lumafluor Inc.,Naples, FL), were made into the dorsal striatum using a 1 µl Hamiltonsyringe (Hamilton, Reno, NE). Coordinates were located 2.7 mmcaudal to the frontal nasal suture, 2.0 mm lateral from the midlinesuture, and 2.5 mm from the surface of the brain. The injectionwas made at a rate of ~0.05 µl/min, and the needle was left inplace for 5 min after injection. By volumetric measurement, ~10%of the lesioned area in the dorsal striatum received injectionsof microspheres. To detect degeneration of dopaminergic neurons,we killed the animals 8 d after MPTP lesion (n = 3/group) andprocessed the animals for TH and Mac-1 immunoreactivity. TH andMac-1 were visualized by incubation with anti-rabbit and anti-ratIgG directly conjugated to fluorescein, respectively, and werevisualized with a laser scanning confocal microscope (LSM 410;Zeiss, Oberkochen, Germany). To identify the cellular origin ofthe sprouted fibers in the dorsal striatum 1 month after the lesion,we killed animals 7 d after tracer injection (n = 5/group) andprocessed the animals for TH immunoreactivity that was visualizedby incubation with anti-rabbit IgG directly conjugated to fluorescein.

Intrastriatal stab wound. Male C57BL6 mice (Harlan Sprague Dawley) at 8 weeks (young-adults) and 8 months (middle-aged) ofage were anesthetized with avertin at 287.5 mg/kg, injected intraperitoneally.The mice were placed on a stereotaxic device. A burr hole wasdrilled on the right side of the skull, and a 1 µl Hamilton syringewas placed into the dorsal striatum. Coordinates were located2.7 mm caudal to the frontal nasal suture, 2.0 mm lateral fromthe midline suture, and 2.5 mm from the surface of the brain.The needle was left in place for 5 min. Animals were killed at4 and 8 d after the lesion (n = 4-5/group).

Isolation of cDNA clones. The IL-1 $alpha$ and IL-1 $beta$ cDNA clones were generously provided by Dr. A. Shaw of Glaxo from which 400and 200 base pair fragments were subcloned into vector pGEM, respectively.The acidic FGF (aFGF) cDNA clone was isolated by PCR of mousestriatal cDNA from which a 350 base pair fragment correspondingto nucleotides 33-384 was subcloned into Bluescript II. The bFGFcDNA clone was generously provided by Dr. S. Shimasaki from whicha 479 base pair fragment corresponding to nucleotides 525-1004was subcloned into vector Bluescript/SK⁺. The glial cell line-derived neurotrophic factor (GDNF) cDNAclone was isolated by PCR of rat genomic DNA from which a 414base pair PCR DNA fragment was subcloned into Bluescript II.

Quantitative solution hybridization nuclease protection assay. Unlabeled sense and high specific activity (~1 × 10⁹ cpm/µg) ³²P-labeled antisense RNAs were transcribed. A standard curve of0-10 µl of 100 fg/µl sense RNA was used for quantitation. Thestandard and known amounts of cytoplasmic RNA isolated were hybridizedwith ~200 pg of antisense ³²P-labeled RNA probe. Samples were heat-denatured at 85°C for 5min and hybridized overnight at 45°C. After hybridization, sampleswere RNase A- (5 µg/ml) and RNase T1- (2 µg/ml) treated for 1hr at 30°C, followed by proteinase K (0.167 mg/ml) digestion at37°C for 15 min. Samples were phenol and chloroform extracted,precipitated, resuspended in 1× Tris-EDTA, and electrophoresedon a nondenaturing 5% acrylamide gel. Gels were dried and quantitatedby phosphorimage analysis. Results were determined by linear regressionanalysis from the standard curve and presented as amoles of mRNA/µgof total RNA.

Statistical analysis. Significant differences in IL-1 $alpha$ , IL-1 $beta$ , aFGF, bFGF, and GDNF mRNA levels between control and MPTP treatmentgroups were analyzed using ANOVA followed by Fisher's protectedleast significant difference post hoc analysis. The level of significancewas set at p < 0.05.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Young mice have the ability to recover after MPTP-induced toxicity of dopaminergic neurons, whereas middle-aged mice do not

Neurochemical assessment
High-affinity synaptosomal dopamine uptake is a sensitive quantitative indicator of dopaminergic axonal terminal density.As shown in Figure 1, determination of dopamine uptake at varioustimes after MPTP treatment revealed an initial comparable lossin dopamine uptake levels in both age groups in the dorsal aswell as in the ventral striatum. In the dorsal striatum, we foundthat MPTP produced a significant reduction in dopamine uptakelevels at 4 d after MPTP in young and middle-aged mice (59 and41% of control, respectively; Fig. 1A). A reduction in dopamineuptake levels in the dorsal striatum was still observed at 8 and14 d in both age groups. However, between 14 and 30 d, a significantrecovery in dopamine uptake levels was observed in young mice.Dopamine uptake levels increased to 87% of control levels afterMPTP treatment in the dorsal striatum of young mice, whereas oldermice did not exhibit such recovery. Thus, we found, in accordancewith others (Ricaurte et al., 1987a), that young mice but notmiddle-aged mice showed substantial recovery of striatal dopaminergicnerve terminals in the dorsal striatum within 1 month.

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Figure 1. [3H]Dopamine uptake after MPTP treatment in the dorsal (A) and ventral (B) striatum of young and middle-aged mice at 4, 8, 14, 21, and 30 d after the lesion. Values are presented as the change in dopamine uptake (expressed as percent of control ± SEM) for n = 4-5 animals per group. The solid line represents young mice treated with a single dose of MPTP at 55 mg/kg, and the dotted line represents middle-aged mice treated with a single dose of MPTP at 40 mg/kg.

Because it has been thought that recovery in the dorsal striatum could arise from spared fibers in the ventral striatum (Giladand Reis, 1979; Hansen et al., 1995; Blanchard et al., 1996),it was important to determine whether the loss and recovery ofdopamine uptake levels in the ventral striatum differ betweenyoung and middle-aged animals after MPTP treatment. In the ventralstriatum, we observed that MPTP produced a significant reductionin dopamine uptake levels at 4 and 8 d in both young and middle-agedmice (Fig. 1B). In young mice, dopamine uptake levels in the ventralstriatum recovered between 8 and 30 d after MPTP treatment, increasingto a level that was greater than that of control values at 14and 21 d (111 to 137% of control, respectively). By 30 d afterMPTP treatment, dopamine uptake levels returned to 85% of controllevels in young mice. In middle-aged mice treated with MPTP, recoveryof dopamine uptake levels was also seen in the ventral striatum.The recovery occurred 1 week later compared with that in youngmice between 14 and 30 d. Similar to young mice, middle-aged miceshowed a greater increase in dopamine uptake levels at 21 d comparedwith levels observed at 30 d after the lesion. The recovery indopamine uptake levels in the ventral striatum exhibited by bothage groups in which the increase was greater than that of controllevels after MPTP treatment suggests that there may be a transientincrease in the affinity or the number of dopamine uptake sitesper terminal.

Morphological assessment
An antibody directed to TH, an enzyme involved in dopamine biosynthesis, is a marker for catecholamine neurons. TH immunocytochemistryrevealed a marked disappearance of TH-immunoreactive (TH-IR) fibersin the dorsal striatum of both young and middle-aged mice as earlyas 4 d after MPTP treatment (Fig. 2B,G), compared with that inage-matched controls (Fig. 2A,F). No marked reduction in TH-IRfibers was seen in the ventral striatum of young mice after MPTPtreatment. However, in middle-aged mice, a modest reduction inTH-IR fibers was observed in the ventral striatum compared withthat in saline-treated animals at 4 d after MPTP treatment thatappeared to recover in TH expression at later time points. A significantloss of TH-IR fibers in the dorsal striatum was still observedat 8 d after MPTP treatment in both age groups (Fig. 2C,H). However,in the dorsal striatum of young mice, a progressive recovery ofTH-IR fibers was observed starting at 14 d (Fig. 2D), reachinga nearly normal staining pattern by 30 d after MPTP treatment(Fig. 2E). In contrast, middle-aged mice did not show such anapparent recovery (Fig. 2I,J).

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Figure 2. TH immunocytochemistry in the striatum of young (A-E) and middle-aged (F-J) mice after saline treatment and MPTP treatment at 4, 8, 14, and 30 d. MPTP caused a marked disappearance of TH-IR fibers in the dorsal striatum of both age groups; however a progressive recovery of TH-IR fibers was observed between 14 and 30 d after MPTP treatment (D, E) in young mice compared with that in middle-aged mice that did not show such apparent recovery. Scale bar, 500 µm.

Dopaminergic cell loss after MPTP treatment

To examine the neurodegenerative effects of MPTP on dopaminergic cell bodies in young and middle-aged mice, we assessed midbrainsections immunostained with TH antiserum. TH immunocytochemistryrevealed a significant depletion of TH-IR cell bodies in the SNof both age groups as early as 4 d after MPTP treatment (Fig.3B,G). In contrast, no marked reduction in TH-IR cell bodies wasseen in the VTA compared with that in age-matched controls (Fig.3A,F). A significant loss of TH-IR cells in the SN remained evidentweeks after MPTP treatment in both age groups (Fig. 3C-E, H-J).At 30 d after MPTP treatment, although a significant depletionof TH-IR cells was found compared with that in saline-treatedanimals, a modest return of TH expression in the SN was observedin young mice (Fig. 3E). This result indicates that in young mice,some of the dopaminergic neurons may survive the MPTP insult andthe transient decrease in TH expression returns as reported byother investigators (Kitt et al., 1986; Sundström et al., 1988).

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Figure 3. TH immunocytochemistry in the midbrain of young (A-E) and middle-aged (F-J) mice after saline treatment and MPTP treatment at 4, 8, 14, and 30 d. MPTP produced a significant loss of TH-IR cell bodies in the SN but not in the VTA of both age groups compared with that in age-matched controls (A, F). Scale bar, 200 µm.

The use of TH-IR neuronal counts has not been a reliable method to measure for MPTP-induced degeneration of dopaminergic neurons.It was shown that MPTP can cause a loss in TH expression withoutproducing neuronal death (Jackson-Lewis et al., 1995). To determinewhether SN dopaminergic neurons are in fact degenerating afterMPTP treatment, we prelabeled SN cells with fluorescent microspheresin young mice before MPTP administration. Young mice were usedbecause they have been suggested to be less sensitive to MPTP-inducedtoxicity than are middle-aged mice (Ricaurte et al., 1986). Theanimals were killed 8 d after saline and MPTP treatment, and midbrainsections were reacted with antibodies to TH and Mac-1, a microgliamarker specific for the mouse (Springer et al., 1979; Beller etal., 1982). In saline-treated mice, retrogradely transported fluorescentmicrospheres labeled the cell body of a subpopulation of TH-IRneurons in the SN (Fig. 4A,B). In MPTP-treated mice, althoughsome fluorescent microspheres were found in TH-IR neurons, theywere also found to be aggregated and scattered throughout theSN (Fig. 4C). Mac-1-IR cells with internalized fluorescent microsphereswere found at the level of the SN cell bodies, suggesting thatmicroglia are phagocytosing degenerating SN dopaminergic neurons(Fig. 4D).

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Figure 4. Dopaminergic neuronal degeneration in young mice at 8 d after MPTP treatment. A, B, Confocal images of TH-IR cell bodies (A) in the SN retrogradely labeled with microspheres (B) in a saline-treated animal. Arrows are in register and show the same location within the same field of view for A and B, indicating that labeled microspheres are within TH-IR cell bodies. C, D, Confocal images showing the distribution of labeled microsphere aggregates (C) and Mac-1-IR microglial cells (D) within the SN of a MPTP-treated animal. Arrows are in register and show the same location within the same field of view for C and D, indicating that Mac-1-IR microglial cells are internalizing the labeled microspheres and suggesting that they are phagocytosing degenerating dopaminergic neurons. Scale bar, 25 µm.

Collateral sprouting of dopaminergic terminals arises from the VTA

To identify the cellular origin of the sprouted fibers in the dorsal striatum of young mice after MPTP-induced injury, weinjected fluorescent microspheres into the dorsal striatum ofsaline- and MPTP-treated animals at 30 d after the lesion whenrecovery of dopamine uptake levels and TH-IR fibers was observed(Fig. 5A,D). The animals were killed 7 d after tracer injection,and the midbrain was reacted with the antibody to TH. In saline-treatedmice, we found a majority (95 ± 0.595%) of cells retrolabeledwith microspheres colocalized with TH-IR neurons in the SN (Fig.5B,C). In MPTP-treated mice, we observed 87 ± 1.231% of cellsretrolabeled with microspheres colocalized with TH-IR neuronsin the VTA, thus suggesting that recovery of the dorsal striatumis mainly attributable to collateral sprouting of axonal fibersin the ventral striatum (Fig. 5E,F). However, because the injectionof the retrograde tracer was made to a localized area and doesnot represent the entire dorsal striatum, we cannot exclude thatremaining SN dopaminergic neurons can also contribute to compensatorysprouting in the denervated striatum.

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Figure 5. Collateral sprouting of dopaminergic axonal fibers arise from the VTA in young mice. A, D, Injection sites of fluorescent microspheres into the dorsal striatum of saline- (A) and MPTP-treated (D) mice are shown. B, C, In a saline-treated animal, fluorescent microspheres (B) were found to colocalize with TH-IR neurons (C) in the SN. E, F, In a MPTP-treated animal, fluorescent microspheres (E) were found to colocalize with TH-IR neurons (F) in the VTA, indicating that most of the sprouting fibers were arising from dopaminergic neurons in the VTA. Arrows are in register and show the same location within the same field of view. Scale bar, 200 µm.

Glial activation

MPTP produces a glial reaction in young mice after MPTP treatment (Francis et al., 1995; Czlonkowska et al., 1996). However,glial responses after MPTP have not been investigated in middle-agedmice. Furthermore, studies have shown that the reactive glialresponse to neuronal injury slows with age (Hoff et al., 1982a,b;Goss et al., 1991). To investigate whether there were differencesin glial responses in young compared with middle-aged mice afterMPTP treatment, we reacted striatum and midbrain sections at varioustimes after the lesion with antibodies to Mac-1 and GFAP.

Microglial reaction
Induction of a microglial reaction in the denervated striatum (confined mainly to dorsal striatum) and the midbrain (confinedat the level of the dopaminergic cell bodies in the SN) was seenas early as 4 d after the lesion in both age groups compared withage-matched controls (Fig. 6). A difference in the morphologyof microglial cells as compared with that in an age-matched controlwas observed in both young and middle-aged mice. In MPTP-treatedmice, the microglia exhibited stronger Mac-1 labeling, largercell bodies, and thicker, less ramified processes compared withthat in saline-treated animals (see Fig. 9H). In young mice, maximalactivation of microglial cells in the striatum was observed at8 d after the lesion, and by 14 d, activated microglial cellswere no longer found (Fig. 6C,D). In middle-aged mice, maximalactivation of microglial cells in the striatum was observed at4 d after the lesion (Fig. 6F); by 8 and 14 d, a modest activationof microglial cells was still visible (Fig. 6G,H). In the midbrain,the peak of change in microglial reaction also occurred fasterin middle-aged mice, as early as 4 d after the lesion comparedwith young mice in which the peak change was observed at 8 d (Fig.6I-K,M-O). By 14 d, activated microglial cells in the midbrainof young mice were no longer found; however, some scattered activatedmicroglial cells were still seen in the midbrain of middle-agedmice (Fig. 6L,P).

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Figure 6. Microglial cells immunoreactive for Mac-1 in the striatum (A-H) and midbrain (I-P) of young and middle-aged mice after saline and MPTP treatment. A, E, Striatum of young and middle-aged saline-treated mice, respectively. B-D, F-H, Striatum of young and middle-aged mice at 4, 8, and 14 d after MPTP treatment, respectively. I, M, Midbrain of young and middle-aged saline-treated mice, respectively. J-L, N-P, Midbrain of young and middle-aged mice at 4, 8, and 14 d after MPTP treatment, respectively. Scale bar, 200 µm.

Astroglial reaction
In both age groups compared with age-matched controls, immunolabeling for GFAP was dramatically increased in the striatumand midbrain as early as 4 d after the lesion (Fig. 7). GFAP-IRastrocytes became hypertrophic, and they exhibited an enlargedcell body and shortened, swollen processes (see Fig. 9F). Maximalactivation of astroglial cells in the striatum and midbrain occurredfaster in middle-aged mice, as early as 4 d after the lesion (Fig.7F,N), compared with young mice in which peak changes were observedat 8 d (Fig. 7C,K). By 14 d, GFAP-IR cells were no longer observedin the striatum of young mice (Fig. 7D); however, an increasein GFAP-IR cells remained distributed in the striatum of middle-agedmice (Fig. 7H). In the midbrain, a modest induction of hypertrophicastrocytes was still found at 14 d after MPTP treatment in bothage groups (Fig. 7L,P). These results indicate that differencesin glial reaction after MPTP exist between young and middle-agedmice and that the reactive glial response was not delayed withage. In fact, middle-aged mice produced a faster and sustainedglial response for 2 weeks compared with that in young mice afterMPTP treatment.

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Figure 7. Astroglial cells immunoreactive for GFAP in the striatum (A-H) and midbrain (I-P) of young and middle-aged mice after saline and MPTP treatment. A, E, Striatum of young and middle-aged saline-treated mice, respectively. B-D, F-H, Striatum of young and middle-aged mice at 4, 8, and 14 d after MPTP treatment, respectively. I, M, Midbrain of young and middle-aged saline-treated mice, respectively. J-L, N-P, Midbrain of young and middle-aged mice at 4, 8, and 14 d after MPTP treatment, respectively. Scale bar, 200 µm.

Induction of IL-1 mRNA is correlated with compensatory sprouting in the denervated striatum of young mice

IL-1 exists in two structurally distinct forms, IL-1 $alpha$ and IL-1 $beta$ , both of which recognize the same receptor and have similarbiological activities (March et al., 1985). To determine whetherIL-1 is regulated in response to MPTP and to examine whether ageinfluences the regulation of IL-1, we analyzed tissues from thesame animals used for dopamine uptake analysis for IL-1 $alpha$ and IL-1 $beta$ mRNA changes by RNase protection assay. As a positive controlfor IL-1 $alpha$ and IL-1 $beta$ changes after MPTP treatment, total RNA fromintrastriatal stab wounds of both age groups was used becauseboth the $alpha$ and the $beta$ forms have been shown to increase after stabinjury (Giulian and Lachman, 1985).

In the dorsal striatum of young mice after MPTP treatment, IL-1 $alpha$ mRNA was significantly increased at 4 d and was maximallyinduced at 8 d after the lesion (518% of control; Fig. 8A). After14 d, IL-1 $alpha$ mRNA remained significantly elevated, and by 30 d,IL-1 $alpha$ returned to control levels in the dorsal striatum of youngmice. In the dorsal striatum of middle-aged mice after MPTP treatment,only a modest increase was observed at 4 and 8 d after the lesion(130 and 135% of control, respectively; Fig. 8B). After 14 d,IL-1 $alpha$ returned to control levels in the dorsal striatum of middle-agedmice after MPTP treatment. Activation of IL-1 $alpha$ synthesis in responseto intrastriatal stab injury was similar in both age groups. Youngmice that received intrastriatal stab wound injury revealed 306and 287% of the control induction at 4 and 8 d after the lesion,respectively (Fig. 8A). Similarly, middle-aged mice revealed 252and 192% of the control increase at 4 and 8 d after the lesion,respectively, after stab injury (Fig. 8B). These results indicatethat the ability to induce IL-1 $alpha$ synthesis in the dorsal striatumafter MPTP dramatically declines with age; however, this strictlydepends on the nature of the injury.

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Figure 8. Quantitative analysis of IL-1 $alpha$ mRNA in the dorsal (A, B) and ventral (C, D) striatum and the midbrain (E, F) of young and middle-aged mice after saline and MPTP treatment at different days after the lesion. The solid lines with open circles represent saline-treated animals, dotted lines with open squares represent MPTP-treated animals, and solid lines with closed diamonds represent animals that received intrastriatal stab wounds. Values represent the mean ± SEM for n = 4-5 animals per group. Levels of statistical significance were set to *p < 0.05, **p < 0.005, and ***p < 0.001, indicating differences from an age-matched control.

Similar to the induction seen in the dorsal striatum of young MPTP-treated mice, an increase in IL-1 $alpha$ mRNA in the ventralstriatum was also seen at 4 d and was maximal at 8 d after thelesion (501% of control; Fig. 8C). After 14 and 30 d, IL-1 $alpha$ mRNAremained significantly elevated. However, in middle-aged mice,no changes in IL-1 $alpha$ mRNA were observed in the ventral striatum(Fig. 8D). The enhanced and extended activation of IL-1 $alpha$ synthesisseen both in the dorsal and ventral striatum of young but notmiddle-aged mice seems best to correlate with the time when MPTP-inducedplastic changes are occurring in young mice.

Although significant changes in IL-1 $alpha$ were observed after MPTP treatment, we did not observe any changes in IL-1 $beta$ mRNA ineither the dorsal or ventral striatum of either age group (datanot shown). However, IL-1 $beta$ mRNA was significantly increased inboth age groups after intrastriatal stab wound injury. The selectiveactivation seen in the $alpha$ form but not the $beta$ form after MPTP treatmentsuggests that the type of injury-induced damage to the brain mayelicit a difference in the IL-1 response.

Because we found microglial activation and an astrocytic response at the site of degenerating cell bodies, we next evaluatedwhether there were changes in IL-1 $alpha$ mRNA in the midbrain afterMPTP lesion. In both age groups, no induction of IL-1 $alpha$ mRNA wasobserved in the midbrain of MPTP-treated mice compared with age-matchedcontrols (Fig. 8E,F). Instead, middle-aged mice exhibited a significantdecrease in IL-1 $alpha$ mRNA at 8 and 14 d after MPTP treatment (Fig.8F). These results suggest that the activation of IL-1 $alpha$ in responseto MPTP is region specific.

Cellular source of increased IL-1 $alpha$ expression

Activated microglia have been shown to be a principal source of IL-1, although there is evidence that astrocytes as well asneurons can synthesize IL-1 (Fontana et al., 1982; Giulian, 1987;Breder et al., 1988; Hetier et al., 1988; Lechan et al., 1990;Tchelingerian et al., 1993). To identify the cellular source ofIL-1 $alpha$ in our MPTP-lesion model, we performed double-labeling immunocytochemistryon the striatum of young mice at 8 d after the lesion, when IL-1 $alpha$ mRNA was detected at its maximal level, using antibodies to IL-1 $alpha$ in combination with either Neu N, a specific marker of neuronalnuclei, GFAP, or Mac-1. In saline-treated young mice, we foundfaint perinuclear localization of IL-1 $alpha$ in Neu N-IR cells (Fig.9A,B). However, in MPTP-treated mice, we observed perinuclearand cytoplasmic staining of IL-1 $alpha$ in Neu N-IR cells (Fig. 9C,D)as well as colocalization of IL-1 $alpha$ and GFAP-IR hypertrophic astrocytesscattered throughout the denervated striatum (Fig. 9E,F). Colocalizationof IL-1 $alpha$ and Mac-1-IR microglial cells was not observed in theseMPTP-treated animals (Fig. 9G,H). These results indicate thathypertrophic astrocytes and neurons are most likely the cellularsources of increased IL-1 $alpha$ expression in the striatum of youngmice after MPTP-induced lesion.

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Figure 9. Cellular source of IL-1 $alpha$ in the striatum of young mice at 8 d after saline and MPTP treatment. A, B, Colocalization of IL-1 $alpha$ (A) and Neu N-IR neurons (B) in a saline-treated animal. C, D, Colocalization of IL-1 $alpha$ (C) and Neu N-IR neurons (D) in an MPTP-treated animal. E, F, Colocalization of IL-1 $alpha$ (E) and GFAP-IR astroglial cells (F; labeled with arrows in E, F) in an MPTP-treated animal. G, H, IL-1 $alpha$ (G) and Mac-1-IR cells (H; labeled with arrows in G, H) showing that IL-1 $alpha$ expression was not distributed in Mac-1-IR microglial cells. Scale bar, 25 µm.

No change in endogenous dopaminergic neurotrophic factor gene expression

Because we and others have reported that intraventricular administration of IL-1 can induce neurotrophic factor gene expression(Spranger et al., 1990; Rivera et al., 1994; Ho and Blum, 1997),we wanted to examine whether changes in dopaminergic neurotrophicfactor gene expression mediate the MPTP-induced plasticity ofdopaminergic neurons. Among the trophic factors expressed in thebrain, aFGF, bFGF, and GDNF are well-characterized dopaminergicneurotrophic factors that can enhance the sprouting of dopaminergicfibers after a neurotoxic damage and can be produced by astrocytes(Date et al., 1990b; Otto and Unsicker, 1990; Tomac et al., 1995).To investigate a potential role for these astroglia-derived dopaminergicneurotrophic factors in MPTP-induced plasticity of dopaminergicneurons, we quantified aFGF, bFGF, and GDNF mRNA in the striatumusing RNase protection assay. No changes in aFGF and bFGF mRNAwere found in the dorsal and ventral striatum of either age group(Fig. 10). In addition, no changes in GDNF mRNA were found in thedorsal striatum of young mice after MPTP treatment (Fig. 10C).

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Figure 10. Quantitative analysis of dopaminergic neurotrophic factor synthesis in the striatum of young and middle-aged mice at different times after MPTP treatment. The solid lines represent young MPTP-treated mice, and the dotted lines represent middle-aged MPTP-treated mice. Values are presented as the change in mean as expressed in percent control ± SEM for n = 4-5 animals per group. A, D, Changes in aFGF mRNA in the dorsal (A) and ventral (D) striatum. B, E, Changes in bFGF mRNA in the dorsal (B) and ventral (E) striatum. C, Changes in GDNF mRNA levels in the dorsal striatum of young MPTP-treated mice.

Localization of IL-1 receptor in TH-IR neurons

Because we observed an induction of IL-1 $alpha$ in the striatum of young mice treated with MPTP and no change in any of the astroglia-deriveddopaminergic neurotrophic factors analyzed, we examined whetherIL-1 $alpha$ could be acting directly on dopaminergic neurons to inducesprouting of axonal fibers. To assess this, we examined the expressionof IL-1 receptor on these neurons. Double-labeling immunocytochemistrywas performed in saline- and MPTP-treated young mice at 8 d afterthe lesion with antibodies to IL-1 receptor and TH. In saline-treatedmice, IL-1 receptor expression was colocalized with TH-IR cellbodies in the SN and VTA throughout the midbrain (Fig. 11A,B).After MPTP treatment, IL-1 receptor expression remained colocalizedwith TH-IR neurons in the VTA and scattered TH-IR cells in theSN (Fig. 11C,D). IL-1 receptor-positive/TH-negative profiles withinthe midbrain were also observed. These results indicate that IL-1 $alpha$ may act as a target-derived neurotrophic factor that enhancesthe plasticity of dopaminergic fibers after MPTP-induced injury.

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Figure 11. TH-IR cell bodies in the midbrain contain IL-1 receptor in saline- and MPTP-treated young mice. A, B, Colocalization of TH-IR neurons (A) with IL-1 receptor expression (B) distributed in the SN and VTA of a saline-treated animal. Upper right-hand panels are high-power magnification of the representative box outlined in the SN. C, D, Colocalization of TH-IR neurons in the VTA (C) with IL-1 receptor expression (D) of a MPTP-treated animal. Scale bars: A-D, 200 µm; high-power magnifications, 50 µm.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Our data are consistent with observations that young mice after MPTP treatment showed a significant recovery of dopaminergicnerve terminals in the dorsal striatum, whereas middle-aged micedid not. In this report, we demonstrated that spared dopaminergicneurons in the VTA were the predominant source of axonal afferentsreinnervating the denervated striatum of young mice. Moreover,because significant recovery of dopamine uptake levels was observedin the ventral striatum of both age groups, this suggests thatthe lack of recovery in the dorsal striatum of middle-aged miceis not attributable to greater damage of the ventral striatum.We found, in fact, that the inability of older mice to supportcollateral axonal outgrowth after MPTP lesion was best correlatedwith the lack of sustained induction of IL-1 $alpha$ synthesis in thedorsal and ventral striatum. Young mice displayed a maximal four-to fivefold greater induction of IL-1 $alpha$ mRNA for an extended periodof time in both the dorsal and ventral striatum compared withthat in middle-aged mice, thus suggesting that IL-1 $alpha$ could playan important role in MPTP-induced plasticity of dopaminergic neurons.

Role for IL-1 $alpha$ in compensatory dopaminergic sprouting after MPTP

The time course of IL-1 $alpha$ induction seen in the dorsal and ventral striatum of young mice directly correlated with the timeperiod of MPTP-induced axonal changes. A progressive recoveryof dopamine uptake levels and TH-IR fibers in the dorsal striatumof young mice was seen between 14 and 30 d after the lesion. Interestingly,our results show that IL-1 $alpha$ mRNA upregulation began 4-14 d afterthe lesion in the dorsal striatum that was just before the detectablerecovery period. Moreover, a similar induction of IL-1 $alpha$ synthesis,but one lasting for much longer periods, up to 30 d after thelesion, was also observed in the ventral striatum of young mice.However, in MPTP-treated middle-aged mice, the induction of IL-1 $alpha$ mRNA was only seen for the first 8 d in the dorsal striatum andnot at all in the ventral striatum. The long-lasting upregulationof IL-1 $alpha$ found both in the dorsal and ventral striatum of youngmice after MPTP treatment suggests a role for IL-1 $alpha$ in eliciting,propagating, or maintaining dopaminergic axonal-sprouting processes.

Our demonstration of IL-1 $alpha$ expression in GFAP-IR hypertrophied astrocytes and striatal neurons indicates that these cellswere the predominant source of increased IL-1 $alpha$ expression in thedenervated striatum after MPTP treatment. Because we did not findIL-1 $alpha$ expression in Mac-1-IR microglial cells, this suggests thatthe induction of IL-1 $alpha$ in the denervated striatum after MPTP treatmentis not occurring within activated microglia but rather in astroglia.The astroglial production of IL-1 demonstrates a functional roleof reactive astrocytes in repair processes but, more importantly,extends their contribution to immunological processes in neurodegenerativedisease. We found that striatal neurons also have the capacityto react to MPTP-induced injury by increased IL-1 expression.This expression in striatal neurons could be a consequence ofMPTP effects to the denervated afferent projections connectedwith the lesioned area. Neurons have been implicated to functionas a source of cytokines (Breder et al., 1988; Lechan et al.,1990; Tchelingerian et al., 1993); however, the role of cytokineproduction in neuronal cell types associated with neurodegenerativedisease has not been described. The data presented open a newperspective on neuron-astroglia interactions associated with thecytokine network during brain function and neurodegeneration.

A striking observation was that activation of IL-1 $alpha$ in response to MPTP is region specific. We found that although a glialreaction accompanied the dopaminergic cell loss in the midbrain,activation of IL-1 $alpha$ mRNA was not observed in the midbrain in eitherage group. In fact, middle-aged mice displayed a significant downregulationof IL-1 $alpha$ mRNA in the midbrain after MPTP treatment. This findingsuggests that the midbrain elicits a different inflammatory mechanismthat is independent of IL-1 $alpha$ activation.

IL-1 $alpha$ effects on dopaminergic axonal sprouting after MPTP treatment may not be indirectly mediated via stimulating enhancedastroglial synthesis of dopaminergic neurotrophic factors as originallyhypothesized. We have described here that the induction of IL-1 $alpha$ mRNA in young mice after MPTP treatment was not accompanied bya secondary induction of astroglia-derived factors such as aFGF,bFGF, or GDNF synthesis; however, we cannot exclude the possibilitythat protein levels may be altered. This finding suggests thatthe synthesis of these dopaminergic neurotrophic factors was notcritical for the lesion-induced plasticity of dopaminergic neurons.Our results are different from data reported by Leonard et al.(1993) in which both aFGF and bFGF mRNAs were found to increasein the denervated striatum at 1 week after the lesion. This differencein results could be a consequence of strain differences or ofthe dosage of MPTP administered (Sundström et al., 1987). Theupregulation of these factors was reported in Swiss-webster micethat have been shown to be particularly resistant to MPTP toxicity(Sundström et al., 1987; Leonard et al., 1993). MPTP toxicitywas shown to be restricted only to fiber damage with no degenerationof dopaminergic neurons in Swiss-webster mice, whereas the C57BL/6strain, which we have used, was shown to display a marked lossof dopaminergic neurons in response to MPTP (Leonard et al., 1993).

In contrast to our original hypothesis that dopaminergic trophic factors could mediate IL-1 $alpha$ lesion-induced plasticity ofdopaminergic neurons, IL-1 $alpha$ may act directly on dopaminergic cells.It has been suggested that IL-1 may act as a target-derived neurotrophicfactor because autoradiography studies have shown a distributionof IL-1 receptor binding in the SN (Farrar et al., 1987; Akaneyaet al., 1995). Our double-labeling experiments revealed that IL-1receptor expression was found within TH-IR cell bodies lying bothin the SN and VTA. We found that after MPTP treatment, IL-1 receptorexpression remained within TH-IR cell bodies particularly in theVTA and in some TH-IR cell bodies scattered in the SN. This findingprovides further evidence of a direct effect of IL-1 $alpha$ on dopaminergiccells. Inhibiting the action of IL-1 $alpha$ by blocking its receptorvia the administration of IL-1 receptor antagonist could be helpfulto assess whether IL-1 $alpha$ is responsible for spontaneous dopaminergicsprouting in young mice after MPTP treatment.

Aging and neurodegeneration

The decline in IL-1 $alpha$ activation in middle-aged mice seems to depend on the nature of the injury, considering that IL-1 $alpha$ wasfound to be induced to a greater extent after intrastriatal stabwound injury. This finding suggests that MPTP propagates a differentialimmune reaction as the brain ages that could lead to the attenuatedrecovery. Hence, understanding immunological responses differingbetween young and aged brain is of great importance, especiallyregarding neural transplants for the treatment of PD. Graftingdopamine-producing tissues such as adrenal medullary chromaffincells or fetal ventral mesencephalon into the striatum of animalmodels of PD and parkinsonian patients have been shown to inducea compensatory sprouting response from residual host neurons andto ameliorate some motor deficits (Bohn et al., 1987; Fiandacaet al., 1988; Lindvall, 1989; Bankiewicz et al., 1991). However,such benefits are greatly diminished in aged animals (Date etal., 1989, 1994). The mechanism of recovery has been difficultto interpret because of limited survival of implanted cells andtissues (Bankiewicz et al., 1988; Fiandaca et al., 1988). Interestingly,it was shown that trauma (cavitation) alone in the striatum promotesa similar functional recovery in hemiparkinsonian monkeys, suggestingthe presence of neurite-promoting factors as a result of the trauma(Plunkett et al., 1990). Inflammatory cells and reactive gliaaround the grafts have been implicated to mediate the transplantation-inducedcompensatory sprouting when intrastriatal implantation of microgliaor activated leukocytes was shown to promote functional recovery(Wang et al., 1991; Ewing et al., 1992). Further investigationdetermined that a key mediator of inflammation in the brain, IL-1,was the potential component through which neural transplants exerttheir growth-promoting effects in parkinsonian animals (Wang etal., 1994). In light of these findings, here we report that althoughmiddle-aged mice showed a faster glial reaction compared withthat in young mice after MPTP treatment, the ability to induceIL-1 $alpha$ dramatically declined with age. Such age-related alterationsin inflammatory reaction could explain the decrease in neurite-promotingactivities and the functional recovery after transplantation ofcells in parkinsonian aged animals.

In conclusion, the present experiments demonstrated that (1) induction of IL-1 $alpha$ mRNA in the dorsal and ventral striatum isassociated with compensatory dopaminergic sprouting, (2) inductionof IL-1 $alpha$ mRNA is region specific and varies with age in responseto MPTP, and (3) IL-1 $alpha$ neurotrophic actions on axonal sproutingmay be directly acting on dopaminergic neurons. Investigatingthe regulation of IL-1 and its interactions with other factors,substrates, and extracellular matrix molecules could lead to abetter understanding of factors attenuating neuronal plasticityin the aging brain and to therapeutic approaches to treating neurodegenerativedisorders.

  FOOTNOTES

Received Feb. 10, 1998; revised May 22, 1998; accepted May 25, 1998.

This work was supported by National Institutes of Health Grant AG-08538. We are grateful to Brett M. Morrison for his helpwith the confocal images and Andrew Leonard for his help withthe figures. We thank Esther García de Yébenes, Patrick R. Hof,Jeremy Kay, and Marie Zurich for their critical review of thismanuscript.
Correspondence should be addressed to Dr. Mariann Blum, Fishberg Research Center for Neurobiology, Mount Sinai School of Medicine,One Gustave L. Levy Place, Box 1065, New York, New York 10029

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Results
Discussion
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